STERLING FLUID SYSTEMS GROUP CORROSION SOLUTIONS WORLDWIDE
STERLING FLUID SYSTEMS GROUP
CORROSION SOLUTIONS WORLDWIDE
1
INTRODUCTION
The annual cost of corrosion and of protection against corrosion inthe world is staggering. A plant may spend considerable amountsof money each year in painting steel to prevent rusting. Corrosionin radiators, exhaust systems and water heaters, increases thiscost further.
The world’s economy would be entirely different if it were not forcorrosion. Even though corrosion is here to stay, its cost can beconsiderably reduced in industry through proper selection ofmaterials, correct design of products, and preventativemaintenance. Corrosion contributes to the depletion of our naturalresources and the recent concern over this is becomingincreasingly influential in inducing people to be ”corrosion-cost“conscious.
In an effort to apply corrosion principles (from fluid flow tounderground soil and atmospheric) to contained chemical systems,and in particular to centrifugal pumps, the following schematicdiagrams have been used (Page 2). These indicate the differentforms of corrosion that may take place in a pump. The diagramsdepict an impeller in a casing. The seals, bearing brackets, etc. areto be imagined.
To view corrosion engineering in its proper perspective, it isnecessary to remember that the choice of material depends onseveral factors:
a. Cost
b. Corrosion resistance
c. Availability
d. Strength
e. Fabrication
f. Appearance
In dealing with pump systems, some other factorsneed to be considered:
a. Suction and operation conditions
b. Continuous/intermittent service
c. Are there several pumpsinvolved, in series, or parallel?
d. Type of seal
e. Flushing fluid
f. Temperature change
The above factors influence the corrosion rates ofany given material, and each is dealt with in detailwhen considering a pump’s hydraulics, but thechoice of a proper material depends on howaccurately these factors have been calculated.Additionally, any changes subsequently made inoperation or processing are critical and may makere-evaluation of the sizing and choice of materialnecessary.
2
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EIGHT FORMS OF CORROSION AND TWO FORMS OF CRACKING PHENOMENAFIG. 1A MECHANICS OF CORROSION
Fig. 1B CRACKING PHENOMENA
General Corrosion Erosion
Localised Corrosion Cavitation
Pitting Crevice/Deposit Corrosion
Galvanic Intergranular (Corrosion)
Stress Corrosion Cracking Corrosion Fatigue
FLOW
BUBBLE
HEAT AFFECTEDZONE
HEAT AFFECTEDZONE
ALLOY R53NOBLE
ALUMINIUMBASE
DYNAMICSTRESS
WELD
WELD
CRACK
STATICSTRESS
3
GENERAL CORROSION
General corrosion leads to relatively uniform thinning. For round bars and wires,corrosion proceeds radially inward at an essentially uniform rate around the entirecircumference. Castings suffer corrosion starting at the wall exposed to the fluid (forexample, the impeller face of the casting) and proceeding gradually and uniformly to theouter wall. Methods of reducing or eliminating general corrosion are the use of coatings,the selection of a more corrosion-resistant material (a general rule is to select an alloywith a higher chrome and/or nickel content), the use of inhibitors, or cathodic protection.General corrosion proceeds by many different means:
A. The corrosion reaction product may be protective; it may form a passivating barrierthat stifles further corrosion. In this case, the material is not inert, but continues tocorrode at a low rate, and to continually repair the passive film. Most corrosion-resistantaustenitic materials, such as stainless steels, show this type of passivating behaviourwith the help of a surface film of oxides. This type of protection is very sensitiveto solids in the pumped fluids. These solids may continually scour away theprotective film which would otherwise form, thus leading to erosion corrosion.
B. The corrosion product may be soluble in the pumped fluid at a ratedetermined by the electrode potential of the metal. This is illustratedvery well when steel is used in oxygenated water.
C. A special case of an artificially controlled uniform dissolutionprocess may be attempted by controlling the pH or current density of agiven solution. This principle is utilised in chemical machining andelectropolishing of stainless steels to improve either the corrosionresistance or frictional characteristics.
In pumps, the recognition of general corrosion is compounded by velocity andpressure variations. The surface casing may show whorls and pockets wherevelocity variations have influenced the rate of corrosion. These variations may appear tobe caused by solids or erosive products in the fluid. However, close examination willalways reveal the fact that corrosion has left an etched appearance on the surface.
CASE HISTORYILLUSTRATINGGENERALATTACK
Alloy: Sterling R52
Environment:30% Hydrochloric Acid withminor impurities.Temperature 66oC.
Description: Notice theattack is all over the surfacewithout an exaggerated effecton the outer periphery. This pump was in service fortwo years.
Remedy: Review cost andevaluate possibility of usinghigher grade alloy, such aszirconium, which is resistantup to 37% HCI to 70 ºC.
CASE HISTORY ILLUSTRATING SEVEREGENERAL ATTACK
Alloy: 316 S.S.
Environment:70% Sulphuric Acid.Temperature 60 oC.
Description: A 316 S.S.impeller was substituted foran R-55 impeller.
Remedy: Do notinterchange castingswithout checkingsuitability ofapplication.
4
Erosion consists of two types of damage modes:
A. Mechanical-chemical or erosion-corrosion
In the erosion-corrosion mode, the flowingliquid may be free of abrasive particles.However, the velocity of the liquid may causeflow aberrations and turbulence due to surfacediscontinuities. The surface discontinuity maybe a weld bead, or flashing in the volute of acasing. This loosely adhered particle isremoved by the liquid velocity, making thedamage look erosive. There is a defined”breakaway velocity“ at which erosion-corrosion begins and is characteristic of agiven alloy/pumped-fluid system.
If this mode is identified and there is noparticle impingement, then reducing the flowrate will help reduce the erosion-corrosion. In
contrast, the removal of the discontinuity may produce the same result.
Impingement of abrasive particles carried by a fluid can affect the surface of the casing, impeller,etc. by causing mechanical damage. The particles are now capable of destroying the protectiveoxide film continually by fluid shear, thereby increasing the rate of damage. In this case, reducingthe flow rate will not help. It is the angle of incidence of the abrasive particle that is of primeimportance. Filtration of these particles wherever possible may be the best solution.
A good example of discontinuity, such as a scratch or a small pit, causing damage is often seen inmechanical seals. In this case, high pressure fluid in the constricted scratch zone causes thedevelopment of a channel. A number of closely knit channels causes the material to “wire-draw”.
This usually reveals itself in a characteristic ripple pattern. The impingement of hard particlescauses multiple cratering. Here the surface undergoes deformation and eventually extrusion. It isthe angle of impingement, velocity, hardness and angularity of the particles that affect this type oferosion. It is extremely sensitive to the flow paths and thus may appear to be localised.
EROSION - CORROSION
CASE HISTORYILLUSTRATING
EROSION
FOR (A) AND (B)
Alloy: 316 S.S.Environment: SodiumNitrate with other solids
SP. GR. 1.24.
Description: Very littledamage around shaft
opening. Outer peripheryshows damage increasing
due to velocity and pressure.By-pass throat area shows
severe damage. Erosionmarks indicate direction
of liquid flow.
Remedy: a) Check rotationon impeller and b)
Substitute with Sterling R48or other more abrasion-
resistant material. This willoften correct the situation.
FLOW
(A)
5
CAVITATION
B. Purely mechanical or particle erosion
In the case of mechanical erosion, the action is limited to the outer periphery of the casing. It ishere that the velocity and pressure of the liquid are the greatest. The central portion around theshaft opening is generally untouched.
Methods of preventing or reducing Erosion-Corrosion can be accomplished by use of one ormore of the following methods. Use materials with improved corrosion resistance to provide astronger protective oxide film. Improve design of system to reduce turbulence. alteration of theenvironment such as filtering to remove solids or reducing the temperature. Use coatings, suchas hard facing, if the coating has the required corrosion resistance, as well, as hardness.Cathodic Protection has been found to reduce Erosion-Corrosion in some applications.
This form of erosion is attributed to the following:
A . Formation of bubbles: At the eye of the impeller the pressure on the liquid is sufficiently
reduced to cause the liquid to vapourise or form bubbles.
B. Collapse of bubbles: As the liquid is now pumped to the outer periphery of the impeller, the
pressure is increased, causing the bubble to implode. Repetition of this process at high speed
causes the bubbles to form and collapse rapidly.
(B)
6
These rapidly imploding bubbles may produce shockwaves with pressure as high as 4400 bar.This is well beyond the yield strength of anumber of materials. Such forces causeplastic deformation in metals, which isindicated by the presence of slip lines on theimpeller and casing.
An imploding bubble causes the metal to beroughened. This roughened area in turn acts as anucleating site for a new bubble to form. Thecollapsing bubbles appear to cause closely-spacedpitted areas and considerable roughening of thesurface. Some measures which can be taken toalleviate this problem are:
A. Change of the design to minimise the hydro-dynamic pressure differences in the process fluid.
B. Use of a more corrosion-resistant material.
CASE HISTORYILLUSTRATING
CAVITATION TYPEDAMAGE
Alloy: Sterling R55.
Environment: Water with50 ppm chloride at 44oC.
Description: Theimploding of bubbles
during re-absorption on thepressure side of the blade
causes damage in the formof closely spaced pits.
Remedy: a) Check theconditions under which the
pump is operating.b) Use a more cavitation-
resistant material.
CASE HISTORYILLUSTRATING
CAVITATION TYPEDAMAGE
Alloy: Sterling R55.
Environment: Water with50 ppm chloride at 44oC.
Description: Theimploding of bubbles
during re-absorption on thepressure side of the blade
causes damage in the formof closely spaced pits.
Remedy: a) Check theconditions under which the
pump is operating.b) Use a more cavitation-
resistant material.
CASE HISTORYILLUSTRATING
CAVITATION TYPE - GAS
CONCENTRATIONCORROSION
Alloy: 316 S.S.
Environment: Unknown.
Description: A restrictedsuction condition caused aninsufficient amount of liquid
to fill the discharge throat,yet a large amount of gas
was present. This caused avacuum on the low velocity
side as shown.
Remedy: a) Review designof suction.
b) Determine if gas in liquidcan be reduced.
C. Smoothing of the finish on the impeller to reducenucleating sites for the bubbles.
D. Use of a rubber or plastic coating that inherentlypossesses a strong metal-coating interface.
E. Cathodic protection can reduce cavitation byforming bubbles on the metal surface, therebycushioning the shock waves produced by thecollapsing bubbles and thus preventing damage tothe metal surface.
Cavitation damage is located anywhere between theinlet eye of the impeller and the tip of the blades.The closely spaced pits are usually seen on thelagging side of the blades. In certain violentinstances, damage is noticed on the leading side ofthe blades. The extent and location of the damage isdependent on the fluid being handled, thetemperature, partial pressures and the degree of re-circulation flow inherent in the design.
7
PITTING
This form of attack is extremely localised. It usually results in a cavity that has
approximately the same dimensions in breadth and in depth. As the breadth
increases, the depth increases, causing a hole through the wall of the casing.
Pits have the following characteristics:
CASE HISTORYILLUSTRATING PITTINGCORROSION
Alloy: 304L S.S.
Environment:Hydrochloric and nitric acidmixtures. Temperature andconcentration unknown.
Description: Severaldamage marks (causedduring material handling)served as nucleating sitesfor an autocatalytic reactionto occur. This resultedin the pits shown.
Remedy: Use alloy withmolybdenum such as CF3M. Methods for combatingCrevice Corrosion generallyapply for pitting. Theaddition of Molybdenum of2% or greater in stainlesssteels contribute greatly inincreasing resistance topitting.
A. They are difficult to detect because they are often covered withcorrosion products.
B. Pits usually grow in the direction of gravity. This is substantiated by thefact that they require a dense concentrated solution for continuing activity.
C. Pitting usually requires an extended initiation period before visible pitsappear. This period ranges from months to years, depending on both thespecific metal and the corrosive liquid.
D. Pitting is autocatalytic. That is, the corrosion processes within a pitproduce conditions which are both stimulating and necessary for thecontinuing activity of the pit.
E. Pitting is usually associated with stagnant conditions. For example, atype 304 stainless steel pump would give good service handling seawater if the pump ran continuously, but would pit if shut down forextended periods of time.
F. Most pitting is associated with halide ions, such as chlorides, bromides,and hypochlorites. Fluorides and iodides have comparatively lesser pittingtendencies. Oxidizing metal ions, such as cupric, ferric, and mercuric incombination with chlorides are considered to be the most aggressive.Non-oxidizing metal ions such as sodium chlorides and calcium chloridesare much less aggressive. This type of corrosion differs from crevicecorrosion in that it creates its own crevice. Materials that are susceptibleto crevice corrosion do not necessarily become susceptible to pittingcorrosion, whereas the reverse may be considered to be true.
8
CREVICE/DEPOSIT CORROSION
This type of corrosion occurs in restricted areas, either metal to metal, (threaded drain plug),or metal to non-metal, (gasketed joints), where free access to the pumped fluid is restricted. Itis aided by the presence of deposits such as sand, dirt, and carbonaceous material that shieldand create a stagnant condition. In certain cases corrosion products will deposit and form acrevice.
As with pitting corrosion, an autocatalytic reaction fosters the growth of crevice corrosion.Thus, the initial driving force is often an oxygen or metal ion concentration cell, but continuedgrowth by accumulation of acidic hydrolyzed salts within the crevice. The external surfacesare protected cathodically.
This kind of attack occurs in many media, however, it is very common in chloride-containingenvironments. It is slow to start, but grows at an ever-increasing rate.There are a number ofactions that can be taken to prevent crevice corrosion:
A. Use of welded joints instead of threaded joints.B. Weld on both sides of a flange to pipe joint, thus avoiding penetration from either side.C. Ensuring that the pump is completely drained.D. Use of gaskets that are non-absorbent, such as teflon, wherever possible.E. Use of flushing in seal areas to avoid stagnant conditions in the bore of the stuffing box cover.
CASE HISTORYILLUSTRATING
CREVICE CORROSION
Alloy: Sterling R55.
Environment: Dilutesulphuric acid with smallamounts of hydrochloric
acid and sodium chloride.Temperature and
concentration unknown.
Description: Thegasketed shielded areahas limited diffusion of
oxidizing ions, thuscreating an imbalance andthe initiation of corrosion.
Note the pitting that isusually associated with
this type of corrosion.
Remedy: a) Review gasketmaterial.
b) Consider welding thejoint between impeller
and shaft
9
GALVANIC
TABLE 1 - GALVANIC SERIESIN PURE SEA WATER
Corroded End (anodic, or least noble)Magnesium
Magnesium Alloys↓
Galvanised Steel orGalvanised Wrought Iron
↓Aluminium
(5052, 3004, 3003, 1100, 6053 in this order)↓
Cadmium↓
Aluminium(2117, 2017, 2024 in this order)
↓Mild Steel
Wrought IronCast Iron
↓NI-RESIST
↓Type 410, Stainless Steel (active)
↓50-50 Lead Tin Solder
↓Type 304, Stainless Steel (active)Type 316, Stainless Steel (active)
↓LeadTin↓
Muntz MetalManganese Bronze
Naval Brass↓
Nickel 200 (active)INCONEL alloy 600 (active)
↓Yellow Brass
Admiralty BrassAluminium Bronze
Red BrassCopper
Silicon Bronze70-30 Copper Nickel
Comp. G-BronzeComp. M-Bronze
↓Nickel 200 (passive)
INCONEL alloy 600 (passive)↓
MONEL alloy 400↓
Type 304, Stainless Steel (passive)Type 316, Stainless Steel (passive)
INCOLOY alloy 825↓
INCONEL alloy 625HASTELLOY alloy C
TitaniumProtected End (cathodic, or most noble)
A potential difference exists between two dissimilar metals whenthey are immersed in a corrosive and conductive solution. If thesemetals are now connected electrically conductively on the outside,an electron flow is produced. One of the two metals will corrodefaster than the other. The metal which is corroding at a faster ratebecomes anodic, while the other metal is cathodic.
The most commonly used series, based on electrical potentialmeasurements and galvanic corrosion tests in unpolluted seawater is shown alongside. (See Table 1).
A similar series is needed for all of the various situations. Thenumber of tests required would be almost infinite. Thus the seriesshould be used only for predicting galvanic relationships. Theseparation between the two metals or alloys in the series is anindication of the probable magnitude of corrosive effects. Effectssuch as polarisation (potential shifts as the alloys tend to approacheach other), area, distance and geometry play a definite role ingalvanic corrosion.
There are several ways in which to combat galvanic corrosion:
A. Material selection is extremely important. Substitution ofimpellers of different alloys in an existing system must be donecarefully. Care should be taken to avoid wide separation in therelevant galvanic series.
B. The pumped fluid may be controlled by the use of a corrosion inhibitor.
C. Barrier coatings and electrical isolation by means of insulatorsto break the electrical continuity are sometimes employed.
D. Cathodic protection by way of using sacrificial metals may be introduced.
E. Design changes involving the avoidance of the unfavourable arearatios, using bolts and other fasteners of a more noble metal thanthe material to be fastened, avoiding dissimilar metal crevices, (as at threaded connections), and using replaceable sections withlarge corrosion allowances of the more active member.
ALUMINIUMBASE
STERLING R53NOBLE
10
INTERGRANULAR CORROSION
In a survey conducted by the Material Technology Institute of theChemical Process Industries, it was shown that sensitisation andresulting intergranular corrosion were the cause of over half of thereported incidents of unsatisfactory performance.
Metals and alloys consist of individually oriented crystals whichform from the molten state (castings or weld metal). These crystalsdevelop into specific atomic arrangements known as crystalstructures (e.g. cubic, hexagonal etc.). These crystal structures canbe manipulated by varying chemistry and heat treatment. Each typeof atomic arrangement has specific physical and mechanicalproperties of its own. Two important arrangements in stainlesssteels are called Ferrite and Austenite. During the solidificationprocess, the development of facets indicative of their crystalstructure is prevented when the growing crystals impinge on eachother. Where the crystals come in contact with each other, theirfacets form a boundary that takes the form of a lattice. Theseboundaries have a much greater degree of structural imperfectionthan within the grains. The resulting energy states at theboundaries can promote the concentration of alloying elements,and of metallic and non-metallic impurities, and of greatestimportance - precipitates.
Sensitisation may be referred to as carbide precipitation in the grainboundaries. The structure of low carbon austenitic stainless steelsconsists of three crystallographic phases: Ferrite, austenite andcarbide under equilibrium condition. Rapid cooling of these steelswill ensure the retention of austenite (a high temperature phase),but if they are heated to around 800oC for any appreciable length oftime, the carbide will precipitate in the grain boundaries. The effectof sensitisation on the chromium and carbon concentration isshown in Figure 3. The figure depicts a transient state only. Figure 2shows the variation in carbon content in passing from one grain,through the grain boundary, to another grain. The chromiumcontent varies in the manner shown in the lower portion of Figure3. There is a narrow region at the grain boundary which containsless than 12% chromium. This is below the 12% chromiumminimum required for corrosion-resistance. If there was no carbonpresent in the alloy, this condition would not be possible.
The sensitisation of an austenitic alloy permits corrosive attack tostart at the grain boundary, (lowest energy level), where there is adeficiency of free chromium. Since the grains (high energy level),are more resistant than the boundaries (low energy level),corrosion follows the boundaries, which is typical of intergranularcorrosion.
In translating this phenomenon to the macro-scale, the attack is firstrecognised as ditching along the grain boundaries, on the surfaceof the casting. As the attack progresses, it permeates the completecasting wall and results in leakage and possible grain dropping. Itshould be noted that cracking, however, does occur in austeniticalloys, and is mainly due to stress corrosion.
EFFECT OF SENSITISATION ON THE CARBON & CHROMIUM CONCENTRATION
GROWING CRYSTAL FACETS FORMING A GRAIN BOUNDARY
AVERAGE CONTENT 0.08%
SATURATION VALUE 0.02%
LEVEL FORRESISTANCE12%
GRAIN BOUNDARY
GRAINBOUNDARY
CA
RB
IDE
PAR
TIC
LEC
AR
BID
E PA
RT
ICLE
18%
% CARBON
% CHROMIUM
HEAT AFFECTEDZONE
HEAT AFFECTEDZONE
WELD
WELD
Fig 3 - EFFECT OF SENSITISATION ON CARBON
AND CHROMIUM CONCENTRATIONS
Fig 2 - LATTICE MISMATCH
11
In practice at the foundry level, it must be mentioned that sensitisation will occur during slowcooling in the mould. Immediate cooling of castings from the mould has been tried. However,the hostility of this production step has limited its applicability. Quench cracks have beennoted in stress concentration areas also. Sensitisation is prevented by providing a solutionanneal above the sensitising range temperature.
CASE HISTORYILLUSTRATINGINTERGRANULARCORROSION (a)
Alloy: Sterling R53.
Environment:25% Hydrochloric acid with100 ppm Chlorine. Temperature: Ambient.a) The impeller on the leftwas solution annealed andthen put in service.b) The impeller on the rightis in the sensitisedcondition. This impeller hasundergone severecorrosion with graindropping occurring at thetip of the blades.
CASE HISTORYILLUSTRATINGINTERGRANULARCORROSION (b)
Alloy: Sterling R53.
Environment:25% Hydrochloric acid with100 ppm Chlorine. Temperature: Ambient.Close-up of the impeller onthe right in (a) above.
12
STRESS CORROSION CRACKING
CASE HISTORYILLUSTRATING STRESS
CORROSIONCRACKING
Alloy: 304L S.S.
Environment:50% Caustic (Sodium
Hydroxide) with trace
amounts of Sodium
Chlorides.
Temperature 66OC.
Description: A drastic
brittle fracture in a ductile
material in a period
of four months.
Remedy: Use another
alloy type.
Two characteristics are necessary for environment cracking to occur: a tensile stress and acorrosion reaction. There are several forms of environmental cracking such as stress corrosioncracking, hydrogen induced cracking, liquid metal cracking, and corrosion fatigue. Generally,cracks produced by this method are unexpected and sometimes are dangerous. They are oftenwrongly interpreted. For example, intergranular corrosion does not require a tensile stress,however, the morphology of the cracks may be very similar to stress corrosion cracking.Welding sometimes produces hot-short cracks which may be identified as stress corrosioncracking.
The stresses that exist in a given situation are usually very complex. The surface net stress incontact with the pumped fluid will be the controlling parameter. The cracks produced areperpendicular to the stress vector. These cracks may be single (as in corrosion fatigue) ormultiple (as in stress corrosion cracking). They may be intergranular or transgranular.
Several of the parameters and the controlling methods used are discussed below:
A. Stress. For a given alloy/fluid system, a threshold stress for cracking exists. In such instances,stresses below the threshold will not cause cracking, but as the stress is increased above thethreshold, cracking is immediately evident. Lowering the residual and thermal stresses by heat-treatment and shot-peening is carried out to decrease the stress levels below the threshold. Thelatter generates compressive stresses in the material which often offset the tensile stressnecessary for cracking to occur. Compatibility of various materials in contact with respect topolarisation of potentials along with geometrics that increase salt ion concentrations (likecrevices) should be considered in detail.
B. Metallurgical: The list of specific environments that aid in stress corrosion cracking is differentfor each major alloy classification. For example, caustics being handled by a carbon steel,chlorides pumped by stainless steel pumps, and copper alloys in an ammonia environment. Themost common method is to utilise another alloy that is not susceptible to this attack.
STATICSTRESS
13
CASE HISTORY
ILLUSTRATING
FATIGUE CORROSION
Alloy: 316 S.S.
Description: A crack
propagated at an inclusion
present in the material after
several months of operation.
CORROSION FATIGUE
This attack results from the cyclic tensile and
corrosive fluid in contact. There is some mystery
in this type of attack due to the fact that failure in
this mode may occur in the absence of corrosive
action. Most of the discussion in stress corrosion
cracking is applicable to corrosion fatigue.
Pump shafts have often failed due to mechanical
fatigue with no contribution by the corrosive. On
the other hand, stress corrosion cracking under
static tensile stress has also
been known to occur. The
phenomenon then covers a
broad spectrum and is
difficult to define clearly.
The importance of microstructure may be illustrated by placing:
1. a sensitised 316 material in a nitric acid solution. Stress corrosion cracking is noticed.2. a solution-annealed 316 material in the same solution. This will not induce cracks.
C. The corrosive liquid in certain cases can be made less effective in causing stress corrosion cracking by the use of an inhibitor such as chromates in a caustic solution. Elimination of the critical chemicals from the liquid is probably the most desirable. A review of the entire system is usually necessary if this attack has been identified.
D. An increase in temperature generally has a detrimental effect, that is, it tends to induce stress corrosion cracking. If, however, the temperature is high enough to remove the criticalchemicals, then the tendency reduces.
E. Coatings and electro-chemical techniques are also used. The coatings normally act as a barrier between the metal and pumped fluid. Electro-chemical techniques are generally used to polarise an alloy to an oxidizing potential out of the range that will cause stress corrosion cracking.
DYNAMICSTRESS
14
CORROSION BY ACIDS
The acids most generally used by industry are
sulphuric, nitric, phosphoric and hydrochloric
acids; and these cause some of the most severe
corrosion problems. The widespread use of these
acids places them in an important position with
regard to costs and destruction by corrosion. In
some cases, corrosion increases with the
concentration of the acid, in others it decreases.
Oxidizing and reducing mixtures of acids and
salts also causes different reactions to different
materials. Velocity and aeration are factors
that must be taken into consideration. Finally,
impurities in the system can cause
severe problems.
SULPHURIC ACIDSelection of a metal for this service depends
primarily on the reducing or oxidizing nature
of the solutions. Below 85% at room
temperature and about 65% up to 66oC, the
acid is reducing and is better handled by
materials resistant to reducing conditions. In
higher concentrations, the acid is oxidizing
and materials resistant to oxidizing media
are essential.
Cast Iron:
Cast irons show good resistance in very strong
sulphuric acids. In a number of instances, it is
more economical to use cast irons, although
the corrosion rates are higher. The resistance
in these alloys is attributed to the graphite
network interfering with the reaction between
the acid and the metallic matrix. In oleum,
however, the acid is known to penetrate the
metal along the graphite flakes, and a little
corrosion in these confined areas builds up
enough pressure to split the iron. This
wedging action is confined to cast irons and is
not apparent in ductile iron, which may be
satisfactory for oleum service.
Types 304 and 316 Stainless Steels:
These stainless alloys are occasionally utilised
for cold, very dilute sulphuric acid and under
conditions that are not strongly reducing
in nature.
Sterling Alloy K26:
This is a very widely used alloy for
applications involving sulphuric acids. It
provides resistance over the entire range of
concentration, including oleum. The
isocorrosion chart reveals the dip in the curve
15
at around 60-80% concentration range at
approximately 66oC. This will maintain the
corrosion rate within 20 mm per year. If the
pump, for example, is to be used
intermittently, then the temperature limitations
may be increased to 82oC. Ferric sulphate and
copper sulphate in the acid act as inhibitors
and decrease attack. Ferric chloride and cupric
chloride in appreciable concentrations are
known to cause pitting.
Sterling Alloy R55:
R55 is a nickel-chromium-molybdenum-copper
alloy that shows outstanding resistance to
sulphuric acid and many other media. It will
withstand the corrosion of both oxidizing and
reducing agents to moderately high
temperatures, (80oC). It is not recommended
for halogen acids or halogen salt solutions in
contact with the material, but provides
resistance over a wide range of oxidizing and
reducing conditions. The 4% copper in the
alloy is kept in solid solution which is essential
for sulphuric acid service. The R55 alloy has
numerous advantages over K26 and is the
most widely used Sterling alloy for sulphuric
acid and most sulphur compounds, such as
sulphur dioxide and hydrogen sulphide gases.
The copper in these alloys does not discolour
the product.
Sterling Alloys R52 and R53:
Alloy R53 is a nickel-chromium-molybdenum
alloy that shows a great deal of thermal
stability at high temperatures. It is useful over
the entire concentration range and oxidizing
conditions. The chromium content in the alloy
provides excellent resistance to oxidizing
conditions. This alloy is very suitable for
chlorides, up to 220 ppm, at a maximum
temperature of 70oC and over the entire
concentration range.
Alloy R52 on the other hand, is a nickel-
molybdenum alloy. This alloy is also known to
possess good corrosion resistance in the
intermediate and strong concentration range
of sulphuric acid. It is better suited to reducing
conditions, and is particularly susceptible to
oxidizing contaminants such as nitric acid,
chlorine, cupric and ferric chlorides, ferric
sulphates, and even aeration.
NITRIC ACIDOne of the most important ingredients for
resistance to nitric acid is chromium. As the
chromium content increases, the corrosion
rate decreases. The minimum amount of
chromium generally accepted is 18%. This
makes the austenitic stainless steels very well
suited for practically all concentrations and
temperatures. The addition of molybdenum to
stainless steels, as in type 316, as opposed to
304, does not improve corrosion resistance to
nitric acid.
Types 304 and 316 Stainless Steels:
Type 304 stainless steel exhibits excellent
resistance to nitric acid at room temperatures
up to 30oC, and also to boiling acids up to
50% strength. The corrosion resistance
decreases as the concentration and
temperature are increased beyond 50% and
30oC. Type 304 does, however, show excellent
resistance to red and white fuming nitric acids
at room temperature.
Because of the susceptibility of sensitised Type
304 (when exposed in the 430oC to 870oC
range) to intergranular attack in nitric acid,
boiling 65% nitric acid (Huey test) is often
used to detect the existence of this condition
prior to fabrication. This is only an indicative
test and is not a prediction of definite behaviour.
16
Nitric acid, when mixed with sulphuric,
phosphoric, or acetic acids, shows reduced
corrosivity to stainless steels and K26 alloys.
On the other hand, mixtures of nitric acid with
hydrochloric or hydrofluoric acid are corrosive
to stainless steels and their rates depend on
concentration and temperatures.
Sterling Alloys R52 and R53:
These alloys are not suited for nitric acid
services as they are readily corroded.
Sterling Alloy R55:
This alloy shows good resistance, but does
not increase resistance sufficiently to justify
the additional cost.
Sterling Alloy R48:
This shows excellent resistance and is
probably the only age-hardenable stainless-
type alloy that shows good resistance, even in
the hardened condition.
Titanium:
This alloy has outstanding resistance at all
concentrations and at temperatures well above
the atmospheric boiling points. It shows less
than 5 mpy in 65% nitric acid at 180oC. It is an
expensive material, but in some cases is the
only material that will do the job. The
presence of oxidizing ions in nitric acid tends
to decrease the corrosion resistance of
titanium - maybe its only drawback.
PHOSPHORIC ACIDPhosphoric acid obtained by the wet process,
is used in the production of fertilisers. The acid
obtained by the electric furnace process is
purer in form and is used in the manufacture
of soap, detergent, food, plasticisers and
insecticides.
Because of the impurities, such as sulphates,
fluorides, and fluosilicates, present in acid
made by the wet process, and the nearly pure
acid from the electric furnace process, the
corrosion behaviour and alloy selection are
based on the manufacturing process. Other
variables include the concentration,
temperature, aeration, etc.
In a number of studies, it has been found that
the cupric and ferric ions in solution inhibit the
corrosion of stainless steels in phosphoric
acid. The cupric ion may be provided by the
initial corrosion of an alloy such as R48 or K26.
On the other hand, the addition of chloride or
fluoride ions to the phosphoric and
hydrochloric or hydrofluoric acid, increases
the corrosion rates by breaking down the
passive film.
There is some debate about stainless steels
that have been affected by sensitising
processes:- corroding intergranularly. Until
there is more evidence, it would be prudent to
use extra low carbon or stabilised alloys for
severe services.
Sterling Alloy K26:
K26 is widely used in phosphoric acid service.
Great care is taken to make sure that the
castings are properly solution-annealed.
CORROSION BY ACIDS :- Continued
17
Sterling Alloy R55:
This is usefully resistant to all concentrations
of phosphoric at temperatures up to 90oC.
Sterling Alloy R52:
This is excellent in hot concentrated pure
phosphoric acid. However, copper ions (an
impurity) behave somewhat differently in
solution. Copper ions at first decrease the
corrosion rate, but beyond about 10 ppm, they
tend to increase the corrosion rate. If this alloy
must be used, the copper content must be
controlled to extremely low values.
Sterling Alloy R48:
This alloy works very well at the same
temperatures and concentrations as K26, is
less expensive and has the added advantage
of handling abrasives better than K26.
Wrought materials used in conjunction with
R48 castings, such as shafts and piping, are
now available.
HYDROCHLORIC ACIDThis is the most difficult of acids to handle
from a standpoint of corrosion. Hydrochloric is
corrosive to most common metals and alloys.
Oxidizing agents and minor impurities such as
ferric chloride (or cupric chloride) and nitric
acid present a very rugged corrosive
condition.
Great care and good judgement is required to
obtain a balance between service life and cost
of the equipment.
Sterling Alloy R53:
This alloy shows good resistance to all
concentrations of hydrochloric acid at room
temperature and has been used successfully
up to 50oC. Due to its high chromium content,
it provides better resistance to oxidizing
environments. It must be kept in mind,
however, that dissolved oxygen is not strong
enough to passivate the material.
Sterling Alloy R52:
R52 is widely used to handle hydrochloric acid
at all concentrations and temperatures up to
the boiling point. Due to the absence of
chromium in this alloy, its resistance to
aeration and oxidizing impurities such as nitric
acid or ferric chloride (when present even in
small quantities) is often destructive.
Types 316SS and Sterling Alloy K26:
The austenitic stainless steels, including K26
are to be used only at very low concentrations
at room temperature. Increasing the
temperature decreases the critical
concentrations at which the stainless steels
start to corrode. Rapid corrosion occurs at pH
4 or 5, or below. Pickling solutions which are
sometimes handled by these materials require
inhibitors if the pump is to be handling the
liquid on a continuous basis.
Nickel and Nickel Irons:
Aeration affects these alloys to a great extent.
They are generally not considered to be
suitable for hydrochloric acid service because
they are susceptible to influences other than
the acid itself and must be used with caution,
only when specific conditions are
definitely known.
Titanium:
This alloy is good up to 10% at room
temperature. The presence of ferric and cupric
chlorides actually decreases the corrosion rate
of titanium.
18
ACETIC ACIDAcetic acid is an intermediate chemical used in
the production of cellulose acetate for paints
and acetic anhydride for artificial fibres.
Various processes are used to produce the
acids, which include:
A. Acetaldehyde Process: The most widely
used process, it has specific problems with
regard to material selection due to catalyst
carry-overs, formation of peroxides and acetic
anhydride.
B. Butane Oxidation: In selection of materials
of construction you must consider formation
of peroxides, formic acid and other solvents
which are typical of this process.
The effect of contaminants is twofold:
1. Contaminants such as sulphur dioxide and
sulphur trioxide increase the corrosion rate.
Formic acid also increases the corrosion rate.
This increased corrosivity can normally be
tolerated by type 316 stainless steel.
2. The presence of aldehydes, ketones and
esters in the process stream have been known
to greatly reduce the corrosion rate.
Acetic anhydride usually will increase the
corrosive attack, especially when the acetic
acid is at 100% concentration. In this instance,
K26 is well-utilised.
Chlorides in the stream have been known to
cause stress corrosion cracking of the
austenitic stainless steels: R53 is usually
recommended if this is the case.
If there is a possibility of temperature increase,
the low carbon grades such as 316L and 304L
should be evaluated to prevent excessive
corrosion and contamination of the acid. The
iron contamination is greatly increased as the
temperature and time of exposure is
increased, especially in the case of 304.
Ferroxyl testing of pumps servicing a
meticulous grade of acetic acid is often done
before shipment. Practice “A” of ASTM A262
(Oxalic Acid Etch), is often recommended as a
qualification test to determine the sensitivity of
the alloy to attack by an acetic acid
environment.
R52 and R53 both provide excellent resistance
to acetic acid at all concentrations and
temperatures. These alloys are more
expensive than type 316 stainless steel and
K26, thus a service life-cost justification should
be done before Sterling types R52 and R53
are utilised.
CORROSION BY ACIDS :- Continued
19
CORROSION BY ALKALIS
Of all the available alkaline materials, caustic
soda (sodium hydroxide) is the most widely
used. It is produced along with chlorine by the
electrolysis of sodium chloride. The type of
electrolytic cell used for production
determines the purity that is obtainable.
Mercuric cells produce 50% grade caustic,
whereas the diaphragm cells produce 9% to
15% grade caustic, which is further purified
before sale.
The major users of caustic soda are the
chemical, pulp and paper, and aluminium
industries.
Iron and steel are widely used at low
temperatures (if iron contamination is not
detrimental), whereas nickel and nickel alloys are
used at higher temperatures.
In concentrations above 75%, and including
molten caustic soda, cast nickel does an
excellent job. When temperatures above
320oC are to be considered, the cast nickel
pump castings should be solution-annealed to
minimise the possibility of graphite
precipitation at grain boundaries and a
resultant loss in ductility.
Velocity and aeration have little effect, except
at high temperatures such as above 540oC.
The thermal decomposition at 260oC of
impurities such as chlorates (present in caustic
soda produced by the diaphragm cell method)
increases the corrosion rate of cast nickel. In
such instances, caustic soda produced by
other methods should be utilised, or reducing
agents such as sucrose or dextrim may be
added to minimise corrosion and product
contamination.
Oxidizable sulphur compounds also tend to
increase the corrosion rate of cast nickel at
elevated temperatures.
Types 304 and 316 Stainless Steels:
The cast versions of austenitic stainless steels
such as types 304 and 316 are used up to 10%
concentration and up to the boiling point of
caustic soda. However, at concentrations
above 10% the critical temperature decreases.
Chlorides in the process stream have been
known to contribute to stress corrosion
cracking of these alloys and consideration
must be given to the stress and temperature
limitations of these alloys.
Sterling Alloy K26:
Pumps made of this material have been used
for handling caustic soda up to 70% and
120oC. Galvanic effects must be considered if
this alloy is to be used with nickel and nickel-
based alloys.
Sterling Alloy R55:
This alloy is used in similar situations to K26. It
provides better stress corrosion cracking
resistance than K26.
Sterling Alloy R52 and R53:
The data available for these alloys is not
sufficient to make any indicative statements.
They have been used up to 50% at the
boiling point.
Ni-Resist Type 2 Cast Iron:
Ni-Resist Type 2 cast iron and spheroidal nickel
iron are both used where minimum
contamination of the product by copper is
desired. These alloys may be used up to 70%
caustic soda concentrations. Stress relief of
these alloys may help minimise stress corrosion
cracking of these alloys.
20
CORROSION BY LIQUID METALS
Heat-transfer characteristics of low boiling
point metals make them particularly attractive
for use in the power plant industries. The
efficiency of a power plant is increased by
operating at higher temperatures. Water and
steam require high pressure equipment which,
besides being hazardous, is also expensive.
The liquid metals and fused salts employed
are usually high thermal conductors. Due to
their low melting points, they save a great deal
in initial heat-up during the start-up of a power
plant. In addition, they require lower pumping
power due to their lower density. For example,
mercury requires very high pumping power,
whereas sodium requires low pumping power.
Liquid metals cause different types of
corrosive attack. The most salient feature is
the lack of electrochemical reactions. In the
simplest type of attack, the solid metal
dissolves in the liquid metal, resulting in
uniform thinning or preferential leaching of a
selective constituent from the solid metal. This
dissolution may result in the formation of
brittle alloy phases.
This kind of uniform thinning also occurs when
solid metal may dissolve at a hot zone of a
pump and precipitate on the walls of a cool
zone, where its solubility is less.
Contact of dissimilar metals with the same
liquid metal can cause transfer of one solid
metal through the liquid metal to the other
solid metal. This causes rapid dissolution
without saturation, leading to destruction.
Finally, impurities such as dissolved gases can
change the solubility limits, the wetting
tendencies, and the activity of the solid
metal ions.
The surface area to volume ratio is of utmost
importance. The greater the ratio, the lower is
the corrosion rate. This is because the greater
the liquid volume, the greater is the amount of
solid metal that can be held in solution.
Types 304 and 316 Stainless Steels:
These alloys may be used to pump sodium
and sodium-potassium mixtures. They have a
temperature limitation of 540oC. If used
intermittently, care should be taken to prevent
carburisation by carbonaceous material. Both
of these alloys can handle lithium, thallium,
mercury, bismuth and bismuth-lead alloys up
to various temperatures.
Grey cast iron: is also good for some of
these liquid metals, such as cadmium and
Bi-Pb-Sn alloys.
Cast nickel: possesses the greatest resistance
to stress cracking in lead, bismuth, tin, and
their alloys. They do not undergo as many
rupture failures as do the nickel chromium
steels.
21
Neither Sterling Fluid Systems, nor any of its officers, directors or employees accept any responsibility for the use of the methods and materials discussed herein.
The information is advisory only and the use of the materials and methods is solely at the risk of the user. Reproduction of the contents in whole or part or transfer
into electronic or photographic storage without permission of copyright owner is expressly forbidden.
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